Abstract
A hypothesis is proposed that the passage of exoenzymes through cell walls occurs more easily through the more plastic and porous nascent cell wall, e. g., the apical region of fungal hyphae. It also accounts for the occurrence of some exoenzymes in cell walls. As the porous and nascent apical wall of fungi is transformed to the less porous lateral wall during growth, some exoenzymes are trapped in transit, thus becoming bound into the wall. Enzymes with binding sites in the wall are not considered in the hypothesis. Several experimental tests performed on Neurospora crassa yield results consistent with its predictions: 1. under selected growth conditions, a group of three exoenzymes of high molecular weight has a significantly higher percent of the total cellular enzyme activity in the wall fraction than another group of three exoenzymes of low molecular weight; this complies with the prediction that larger molecules are more easily trapped in transit, 2. during germ tube outgrowth and early log phase, when the relative amount of surface area occupied by hyphal tips is larger than in older cultures, there is decreased molecular sieving of secreted exoenzymes as judged by a) a smaller proportion of the secreted invertase, comprising light invertase (mol wt=51,500) and heavy invertase (mol wt=210,000), being in the light form, and b) a larger amount of proteins with molecular weights over 40,000 than those of 20,000–40,000 in the culture filtrate. Some of the possible applications of the hypothesis to other microorganisms are discussed.
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Chang, P.L.Y., Trevithick, J.R. How important is secretion of exoenzymes through apical cell walls of fungi?. Arch. Microbiol. 101, 281–293 (1974). https://doi.org/10.1007/BF00455945
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DOI: https://doi.org/10.1007/BF00455945